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Natural variations in the promoter of OsSWEET13 and OsSWEET14 expand the range of resistance against Xanthomonas oryzae pv. oryzae

  • Abha Zaka,

    Roles Data curation, Formal analysis, Investigation, Methodology, Software, Writing – original draft, Writing – review & editing

    Affiliations Agriculture Biotechnology Division, National Institute for Biotechnology and Genetic Engineering (NIBGE), Jhang road, Faisalabad, Punjab, Pakistan, Department of Biological Sciences, Pakistan Institute of Engineering and Applied Sciences (PIEAS), P.O. Nilore, Islamabad, Punjab, Pakistan

  • Genelou Grande ,

    Contributed equally to this work with: Genelou Grande, Thea Coronejo, Ian Lorenzo Quibod

    Roles Data curation, Methodology, Software

    Affiliation Rice Breeding Platform, International Rice Research Institute, Metro Manila, Philippines

  • Thea Coronejo ,

    Contributed equally to this work with: Genelou Grande, Thea Coronejo, Ian Lorenzo Quibod

    Roles Data curation, Methodology, Software

    Affiliation Rice Breeding Platform, International Rice Research Institute, Metro Manila, Philippines

  • Ian Lorenzo Quibod ,

    Contributed equally to this work with: Genelou Grande, Thea Coronejo, Ian Lorenzo Quibod

    Roles Data curation, Methodology, Software

    Affiliation Rice Breeding Platform, International Rice Research Institute, Metro Manila, Philippines

  • Chun-Wei Chen,

    Roles Conceptualization

    Affiliation Taiwan Agricultural Research Institute, Agricultural Research and Extension Station, Council of Agriculture, Guannan, Miaoli District, Taiwan

  • Su-Jein Chang,

    Roles Conceptualization, Funding acquisition

    Affiliation Taiwan Agricultural Research Institute, Agricultural Research and Extension Station, Council of Agriculture, Guannan, Miaoli District, Taiwan

  • Boris Szurek,

    Roles Formal analysis, Methodology

    Affiliation IRD, CIRAD, Université Montpellier, IPME, Montpellier, France

  • Muhammad Arif ,

    Roles Conceptualization, Funding acquisition

    ‡ These authors also contributed equally to this work.

    Affiliations Agriculture Biotechnology Division, National Institute for Biotechnology and Genetic Engineering (NIBGE), Jhang road, Faisalabad, Punjab, Pakistan, Department of Biological Sciences, Pakistan Institute of Engineering and Applied Sciences (PIEAS), P.O. Nilore, Islamabad, Punjab, Pakistan

  • Casiana Vera Cruz ,

    Roles Conceptualization, Funding acquisition

    ‡ These authors also contributed equally to this work.

    Affiliation Rice Breeding Platform, International Rice Research Institute, Metro Manila, Philippines

  • Ricardo Oliva

    Roles Conceptualization, Funding acquisition, Project administration, Supervision, Writing – review & editing

    r.oliva@irri.org

    Affiliation Rice Breeding Platform, International Rice Research Institute, Metro Manila, Philippines

Abstract

Bacterial blight, caused by Xanthomonas oryzae pv. oryzae (Xoo), is one of the major diseases that impact rice production in Asia. The bacteria use transcription activator-like effectors (TALEs) to hijack the host transcription machinery and activate key susceptibility (S) genes, specifically members of the SWEET sucrose uniporters through the recognition of effector-binding element (EBEs) in the promoter regions. However, natural variations in the EBEs that alter the binding affinity of TALEs usually prevent sufficient induction of SWEET genes, leading to resistance phenotypes. In this study, we identified candidate resistance alleles by mining a rice diversity panel for mutations in the promoter of OsSWEET13 and OsSWEET14, which are direct targets of three major TALEs PthXo2, PthXo3 and AvrXa7. We found natural variations at the EBE of both genes, which appeared to have emerged independently in at least three rice subspecies. For OsSWEET13, a 2-bp deletion at the 5th and 6th positions of the EBE, and a substitution at the 17th position appear to be sufficient to prevent activation by PthXo2. Similarly, a single nucleotide substitution at position 10 compromised the induction of OsSWEET14 by AvrXa7. These findings might increase our opportunities to reduce pathogen virulence by preventing the induction of SWEET transporters. Pyramiding variants along with other resistance genes may provide durable and broad-spectrum resistance to the disease.

Introduction

Rice provides more than 20% of the total caloric intake for half of the world’s population [1]. Under irrigated environments, bacterial blight (BB) represents one of the major biotic constraints to sustain rice production. The disease can easily spread across large cultivated areas causing up to 30% of yield losses [2]. Up to now, the most effective way to control disease epidemics in the field is the introgression of genetic resistance into elite varieties. Development of resistant rice varieties, by pyramiding multiple resistance genes, is a cost-effective disease management strategy as it reduces the net cost for crop production and therefore substantially preserves the yield potential [3].

Disease symptoms are caused by Xanthomonas oryzae pv. oryzae (Xoo), which enters the rice host through wounds or hydathodes and establishes itself in the vascular tissues [4]. For further proliferation in the xylem, Xoo relies mainly on type III secretion system-mediated translocation of effector proteins into the host cell. Type III effectors (T3E) mimic host proteins to modulate plant defense response and facilitate access to host nutrients [5, 6]. At least two groups of T3E with a measurable contribution to pathogenesis have been identified. The first group, recognized as Xanthomonas outer proteins (Xop), appears to suppress plant innate immunity using diverse biochemical mechanisms [79]. The second group includes transcription activator-like effectors (TALEs), which induce the expression of host susceptibility (S) genes to promote a favorable environment for the bacteria [6]. TALE-mediated activation usually occurs by sequence-specific recognition of effector binding elements (EBEs) in the promoter sequence of host target genes [10].

Major TALEs in the global Xoo population target at least one of three members of the SWEET sucrose-efflux transporter family [1114], although, potentially five members of clade III SWEETS can serve as susceptibility genes [12]. The EBE of OsSWEET11 and OsSWEET13 are the main targets of Asian Xoo populations carrying PthXo1 and PthXo2, respectively [12, 14, 15]. In the same way, Xoo also evolved AvrXa7, PthXo3 in Asian [11] and TalC and Tal5 in African populations to target at least three EBEs in the promoter of OsSWEET14 [12, 16, 17]. This pattern of evolution aligns to the hypothesis that OsSWEET activation increases sugar availability within the xylem vessels, providing nutrients during bacterial colonization [18, 19, 12].

Similar to other plants, rice uses multiple mechanisms to defend itself against Xoo invasion. A number of resistance genes (Xa) evolved to recognize the activity of TALEs and activate defense response. That is the case of Xa23, Xa27, and Xa10, a unique class of decoys activated by cognate TALEs AvrXa23, AvrXa27, AvrXa10 and to trigger cell death [20, 21]. On the other hand, rice blocks the pathogens’ access to sugars as a way to promote Xoo starvation and prevent colonization [22]. It has been shown that natural variations disrupting the EBE of OsSWEETs generate resistance phenotypes [23]. For instance, PXO99 strain, which carries the PthXo1 effector, is unable to grow on plants carrying the recessive loss-of-susceptibility “resistance” gene xa13 [6]. A single substitution in the OsSWEET11 promoter (xa13) alters the binding specificity of PthXo1, preventing it from activating the gene [23, 24]. In fact, a number of allelic variants of OsSWEET11 have been found to be non-responsive to PthXo1 [13, 18, 23].

Lately it was found that TALEs may evolve by codon substitutions and deletion of individual repeats, or reassortment within TALE clusters [25]. These mechanisms are likely to create novel specificities capable of activating unresponsive target variants. Therefore, looking for promoter variants of OsSWEET in rice germplasm is of immense importance to expand the level of protection against the pathogen. In the current study, we explored genomic information from more than 3000 rice accessions to identify natural allelic variation on the promoter sequence of OsSWEET13 and OsSWEET14 that might expand the level of resistance to Xoo. We also tested whether some SNPs/InDel at the relevant EBEs is enough to prevent induction of both OsSWEET genes.

Material methods

In silico mining of a rice diversity panel

For in silico mining of OsSWEET13 and OsSWEET14, we analyzed the promoter regions of LOC_Os12g29220 and LOC_Os11g31190, as evidenced in the Nipponbare rice genome annotation project [26]. Using the Rice SNP-seek database [27], we searched for genetic variation in a diversity panel containing 3000 rice genome sequences. Accessions were pre-selected with variations within 1.5kb region upstream of the transcription initiation site of both OsSWEET genes. The default setting of the program TALVEZ was used for prediction of the EBE of PthXo1, PthXo2, PthXo3, AvrXa7, TalC, and Tal5 in the promoter of pre-selected accessions [28]. The software uses the repeat variable diresidues (RVD) pattern of each TALE to assess sequence specificity in the rice genome. In the second phase of mining, only accessions with SNP/Indels in the predicted EBE were retained. In addition, selected lines with desirable SNP/Indels from the Pakistani aromatic rice breeding program were also analyzed [29]. The Rice SNP-seek database was used to assess the presence of Xa4, xa5, Xa7, xa13, and Xa21 in selected accessions [3033].

Phylogenetic reconstruction

In order to reconstruct the phylogenetic relationships of the selected accessions, three family members (Os03g37490, Os0629950, and Os10g20450) of the multidrug and toxic compound extrusion (MATE) cluster were selected. MATE gene family has been previously reported for explaining different evolutionary trends in Arabidopsis and rice [34]. Information regarding start and end position of these MATE genes was obtained from rice genome annotation project [26] and used to extract SNPs from a subset of 366 accessions. An unrooted neighbor-joining tree was constructed with DARwin 6.0.14 software with a bootstrap value of 1000 [35], and the matrix of genetic distances was calculated using the Euclidian distance.

Plant growth conditions and pathotyping

Seeds of selected accessions (S1 Table) and IR24 (as a susceptible check) were obtained from International Rice Genebank (IRG) at the International Rice Research Institute (IRRI), Philippines and pre-germinated at 37°C for 3 days. Only healthy seedlings were selected and transferred to large pots in the greenhouse. Six reference Philippines Xoo strains containing known TALE variants were selected for inoculation i.e. PXO339 carrying PthXo2.1, PXO86 carrying AvrXa7, PXO61 carrying PthXo3, PXO282 carrying PthXo2/AvrXa7, PXO602 carrying PthXo2/AvrXa7.1, and PXO99 carrying PthXo1. Additional strains with unidentified TALEs were also selected, i.e. PXO513, PXO404 and PXO562 (S2 Table). Bacterial inoculum was prepared from three days old pure culture in distilled sterile water with an optical density of 0.2 (OD600) and concentration of 1x10-8 - 1x10-9 CFU/mL. For pathotyping, fully expanded, 3–5 leaves of 21 days and 45 days old plants were clip inoculated [36]. The experiment was replicated three times independently. Data regarding lesion length for each inoculated strain on selected accessions and susceptible check (IR24) was recorded at 14 days post-inoculation (dpi) when lesions were stable. Disease incidence was scored according to IRRI Standard Evaluation System (SES) for rice [37].

Sequence analysis of predicted EBEs

Three young leaves per accession were harvested, ground in liquid nitrogen and genomic DNA was extracted using the standard CTAB method [38]. DNA was quantified and normalized by ND-1000 NanoDrop spectrophotometer (NanoDrop Technologies; http://www.nanodrop.com) to a concentration of 70ng/μl. Predicted EBEs in Ejali, Khama1183, Super Basmati (SB) and IR24 were amplified using EBE-specific markers (S3 Table). For each PCR reaction, 1.3 μl of DNA, 14.2 μl of UltraPure™ DNase/RNase-free distilled water, 2 μl of 10X buffer, 0.4 μl of 10mM dNTPs, 1 μl of each primer (forward and reverse with a stock concentration of 100 μmol and working concentration of 5 μmol) and 0.1 μl of Taq DNA polymerase was used. Amplification was performed on G-Storm GS1 thermal cycler with an initial denaturation step at 95°C for 5 min, denaturation at 94°C for 30sec, annealing at 94°C for 30sec and extension at 72°C for 1min followed by 34 cycles and ending with a final extension step at 72°C for 10min. PCR amplified products were resolved on 1.2% agarose gel. The amplified product was eluted from the gel and purified using QIAquick Gel Extraction Kit (QIAGEN Sciences, Maryland 20874, USA). Purified products were bidirectionally Sanger sequenced using commercial services and chromatograms were compared to evaluate sequencing quality. Sequenced PCR products were aligned with the reference genome (Nipponbare) using CLUSTALW [39].

Gene expression analysis

To analyze transcript accumulation of OsSWEET13 and OsSWEET14 in response to Xoo infection, we infiltrated rice accessions with tester strains containing known TALEs. Plants were grown under controlled environment (28°C and 26°C day and night temperature respectively with a relative humidity of 90%) and artificially inoculated with PXO339 carrying PthXo2.1 and PXO86 carrying AvrXa7. In addition, recombinant PXO99TalC (carrying TalC) was used to assess the alternative activation of OsSWEET14 and the empty vector PXO99EV as a control. Twenty-four hours post infiltration (hpi), a total of nine leaves were pooled and stored in liquid nitrogen. Total RNA was extracted using the TRIzol (Invitrogen) method with minor modifications [40].

Quality and concentration of total extracted RNA were measured by 1.65% formaldehyde agarose gel. Five micrograms of RNA from each Xoo infiltrated accession was separately treated with amplification-grade DNase1 (Invitrogen) followed by cDNA synthesis using the Super Script® III cDNA synthesis kit (Invitrogen). cDNA derived from 5μg of total RNA was used for each real-time PCR with gene-specific primers (S3 Table). Rice gene Actin was used as internal control. The qRT–PCR was performed on Applied Biosystems StepOnePlus RT-PCR system using the PowerUp™ SYBR™ Green Master Mix (Thermo Fisher Scientific). The average threshold cycle (Ct) was used to determine the fold change of mRNA level. The 2ΔΔCt method was used for relative quantification of mRNA accumulation [41].

Results

Mining of OsSWEET13 and OsSWEET14 promoter polymorphisms in a large database identified potential new sources of resistance

Mining for variations in the promoter sequence of OsSWEET13 and OsSWEET14 in the 3k SNP-seek database resulted in 631 accessions with SNPs/InDels within the region 1.5kb upstream of both genes. Based on the phylogenetic tree, different incidence of SNP/InDels was found in the four rice subspecies. Variations in the promoter region from O. sativa subspecies indica, japonica, aus, and aromatic accessions showed relative frequencies (expressed in percentage) of 10.75, 2.65, 0.12, 0.64 for OsSWEET13 and 10.91, 0.12, 0.08 and 0.04 for OsSWEET14, respectively (Fig 1). Selected accessions from initial mining were further screened to filter out those with SNPs/InDels specifically at the EBE regions. As a result, we selected 41 accessions (S1 Table) with SNPs/InDel variants in the EBE targeted by PthXo2.1, PthXo3, and AvrXa7. The highest relative frequency of EBE mutation for OsSWEET13 was observed in japonica accessions (1.08) while it was minimum (0.08) in aus accessions. For OsSWEET14, the relative frequency of EBE mutation was greater in accessions of japonica subgroup (0.08) and lowest (0.04) in accessions of indica subgroup (Fig 1).

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Fig 1. Relative frequency (RF) of mutations (expressed in percentage) in the promoter region of OsSWEET13 and OsSWEET14 found in four rice subspecies.

The tree topology was constructed using three multidrug and toxic compound extrusion (MATE) genes on a subsample of 366 random accessions. RF of natural variations in the promoter region (circles) and effector-binding element site (squares) of OsSWEET13 and OsSWEET14 was calculated based on 3,000 rice accessions. For each rice subspecies, RFs were computed by dividing the number of accessions of that subspecies with natural variations (in promoter region and EBE site) to the total number of accessions in the database and multiplied with 100 to express in percentage. Mutations were more frequently found in japonica, aus and indica subspecies. No aromatic accessions contain EBE specific mutations for both OsSWEET genes.

https://doi.org/10.1371/journal.pone.0203711.g001

Other than 3K SNP-seek panel, the aromatic germplasm collection [29] was also mined to identify lines with variation in OsSWEET13 or OsSWEET14 EBEs. Among the accessions that have breeding value, we found the aromatic variety Super Basmati (SB) to have SNPs/InDels in the OsSWEET13 EBE which is targeted by PthXo2.1. None of the selected accessions have SNPs/InDels at the predicted EBE targeted by PthXo1 (Part A of S1 Fig). To assess the resistance spectrum of the selected accession we phenotyped all 41 entries against reference strains carrying PthXo2.1, PthXo3, and AvrXa7 (S2 Fig). Thirty-nine of 41 selected accessions showed a decrease in lesions length (LL) ranging from 0.74 cm to 4.75 cm when challenged with PXO339 in comparison with IR24 (susceptible check) i.e. 27.15 cm. Three accessions exhibited reduced lesion length, ranging from 1.9 cm to 5 cm, when challenged with PXO86. Two accessions showed decreased lesion length ranging from 1.5 cm to 3 cm against PXO61 compared with the susceptible check. Interestingly, we found 2 accessions from the aus subgroup, named Ejali and Khama1183, with reduced disease incidence (LL < 5) for all three tested strains (S2 Fig). Hence, Ejali and Khama1183 with pyramided SNPs/InDels in the corresponding EBE of PthXo2.1, PthXo3, and AvrXa7 along with SB were selected for further analysis. As expected, Ejali, Khama1183, and SB were susceptible to PXO99 (Part B of S1 Fig).

Novel variations identified within OsSWEET13 and OsSWEET14 promoter regions

Variations in the EBE of OsSWEET13 and OsSWEET14 that affect susceptibility have been described earlier [42, 28]. To validate if the identified SNP/Indels represent novel variants, the regions of the predicted EBE of Ejali, Khama1183, and SB were amplified, sequenced and compared to the reported sequences. Interestingly, novel polymorphisms in the regions targeted by PthXo2, PthXo3 and AvrXa7 were identified (Fig 2). Sequence alignment of predicted EBE in the promoter of OsSWEET13 in Ejali and Khama1183 with the one in Nipponbare and IR24 confirmed the presence of 2-nucleotide deletion after the putative TATA box region that matches the RVD at position 5 and 6 (Fig 2A). A related deletion was reported by Zhou at al. [14]. Similar to the Nipponbare variant, SB harbors a single nucleotide deletion at position 6 and an additional “T to A” substitution at position 17 (Fig 2A). These natural variations in the EBE of OsSWEET13 lead to mismatches for three RVDs i.e. NN, NI and HG of PthXo2. For OsSWEET14, sequence alignment of predicted EBE in Ejali and Khama1183 validated the presence of a novel single “C” to “G” substitution that matches the RVD at position 10. This single nucleotide substitution in Ejali and Khama1183 generates a gap for RVD “HD” of PthXo3 and AvrXa7. Like IR24, SB did not show any variation in the respective EBE of OsSWEET14 (Fig 2B).

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Fig 2. Identification of novel allelic variations in the promoter region of OsSWEET13 and OsSWEET14.

(A) Alignment of reported indica, japonica, identified aus and aromatic version of OsSWEET13 effector-binding element (EBE) showing deletions and substitution at position 5, 6, and 17 targeted by PthXo2.1. (B) Alignment of reported indica, japonica, identified aus and aromatic version of OsSWEET14 EBE showing a single substitution at position 10 targeted by PthXo3 and AvrXa7. Nucleotide substitutions and deletions are highlighted red, and hyphens, respectively. The repeat variable diresidues (RVD) for PthXo2.1, PthXo3, and AvrXa7 are shown in top of each alignment.

https://doi.org/10.1371/journal.pone.0203711.g002

Mutations at the EBE appear to prevent activation of OsSWEET13 and OsSWEET14

The activation of OsSWEET13 and OsSWEET14 by tester Xoo strains PXO339, PXO86, and PXO61 have been reported for IR24 [16, 43]. To test if the identified SNPs/Indels in the EBE of OsSWEET13 and OsSWEET14 were sufficient to alter the activation of these genes, we inoculated 3-week old plants with tester strains and measured transcript accumulation of both genes after 24 hpi (Fig 3). As expected, PXO339 triggered 18-fold induction of OsSWEET13 in IR24. Expression of OsSWEET13 in Khama1183 (0.82-fold) and Ejali (3.12-fold) was restricted (Fig 3A). Although SB features a different type of allelic variation in the EBE, transcript accumulation of OsSWEET13 in SB was also reduced by 0.22-fold relative to the mock (Fig 3A). In the same way, we observed similar levels of OsSWEET14 expression in Khama1183 (1.8-fold) and Ejali (0.27-fold) when challenged with PXO86. By contrast, expression of OsSWEET14 in IR24 (15.5-fold) and SB (6.5-fold) was strongly induced that carry an intact EBE (Fig 3B). To further investigate if OsSWEET14 is inducible when a different EBE is targeted, we used TalC to activate the mutated version of the gene. We found that OsSWEET14 can be induced by PXO99TalC (3.96-fold) in leaves of Khama1183 but not by PXO99EV or PXO86 (Fig 3C).

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Fig 3. Effector-binding element (EBE) specific mutations prevent the activation of OsSWEET13 and OsSWEET14 by Xanthomonas oryzae pv. oryzae (Xoo).

Each bar represents average folds change in relative expression at 24 hours post inoculation. Vertical lines on each bar represents ± standard deviation (SD) among three replicates. (A) Transcript accumulation of different version of OsSWEET13 in mock and PXO339 (carrying PthXo2.1) inoculated plants. (B) Transcript accumulation of different versions of OsSWEET14 in mock and PXO86 (carrying AvrXa7) inoculated plants. (C) Activation of OsSWEET14 is possible when a different EBE is used in PXO99TalC inoculated plants.

https://doi.org/10.1371/journal.pone.0203711.g003

In silico and PCR profiling indicate absence of major Xa genes that explains the phenotype

To further validate the assumption that reduced disease incidence is associated to impaired expression of OsSWEET13 and OsSWEET14 in Khama1183, Ejali, and SB, we checked the presence of Xa4, xa5, Xa7, xa13, and Xa21 using the 3,000-genome information or PCR linked markers. Among them, Xa7 and Xa4 appear to be present in Ejali and Khama1183 but none of these genes are known to stop PXO339 or PXO99. In the case of PXO86, which have AvrXa7, resistance due to the putative presence of Xa7 can not be discarded. The recessive xa5 is an allelic version of the TFIIA-gamma transcription factor subunit that reduces the expression of SWEET genes and impairs pathogen colonization [44, 45]. In silico and PCR results revealed that Ejali has both alleles of the TFIIA-gamma transcription factor subunit in homozygous recessive state (xa5/xa5), Khama1183 has heterozygous alleles (Xa5/xa5), and SB has both homozygous dominant alleles (Xa5/Xa5) (S3 Fig).

Xoo strains with PthXo2 and AvrXa7 variants cannot colonize accessions with EBE-specific mutations

To estimate the level of variation among TALEs in relation to the polymorphic sites found in OsSWEET13 and OsSWEET14 EBEs, we aligned the RVD sequences of PthXo2 and AvrXa7 with other allelic variants. Both, PthXo2 and PthXo2.1 have similar RVDs except at position 17, where “HG” changes to “NG” (Fig 4A). While these mutations might have distinct binding specificity, we found a naturally existing substitution (“T to A”) at this same particular position in the EBE site of SB OsSWEET13. In contrast, AvrXa7 and AvrXa7.1 show significant number of RVDs changes. Interestingly, the substitution at position 10 (“C to G”) aligned to a conserved RVD (“HD”) in AvrXa7, and AvrXa7.1, but also in PthXo3 (Fig 4B).

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Fig 4. Selected accessions confer broad-spectrum resistance against Xanthomonas oryzae pv. oryzae (Xoo) carrying different variants of PthXo2 and AvrXa7.

(A) Alignment of different versions of OsSWEET13 effector-binding element (EBE) with the repeat variable diresidues (RVDs) of PthXo2 and PthXo2.1. (B) Alignment of different versions of OsSWEET14 EBE with the RVDs of PthXo3, AvrXa7 and AvrXa7.1. (C, D) Phenotypic response and average lesion length of selected accession inoculated with Xoo strains PXO282, PXO602, PXO339 carrying PthXo2 and PthXo2.1, PXO86, PXO282, PXO602 carrying AvrXa7 and AvrXa7.1, PXO61 carrying PthXo3, and PXO404, PXO513, PXO562 carrying unidentified TALe targeting both OSWEET13 and OSWEET14. Accessions were clip inoculated and accessed after 14 days post inoculation. Each bar represents average lesion length of three replicates. Vertical lines on each bar represents ± standard deviation (SD) among three replicates.

https://doi.org/10.1371/journal.pone.0203711.g004

To further investigate whether Xoo strains with allelic variations of PthXo2 and AvrXa7 have potential to colonize the selected accession, we clip-inoculated 21-day old plants with PXO339, PXO86, PXO61, PXO282, and PXO602 representing known TALE variants [46]. In addition we inoculated with PXO513, PXO404, and PXO562 representing a diverse set of virulent strains of Xoo. Disease incidence was scored at 14dpi (Fig 4C). Pathotyping results demonstrated that Khama1183 shows broad-spectrum resistance against all tested Xoo strains carrying different versions of TALEs. For Khama1183, average lesion length (LL) against tested versions of PthXo2, PthXo3, and AvrXa7 ranged from 2.73 cm to 4.74 cm compared with susceptible IR24 (Fig 4D). We also found that SB was colonized by Xoo strain carrying PthXo2 but not by strains carrying PthXo2.1 (Fig 4D).

Discussion

Plants utilize a number of mechanisms to protect themselves against pathogens. Triggering immunity or disrupting pathogen access to nutrient supply are common strategies that plants evolved to restrict the invading microbes [22]. Understanding how rice limits sugar effluxes will provide a good opportunity to elevate disease resistance against Xoo. Since members of the SWEET sucrose-efflux transporter family appear to be hijacked by different Xoo populations, pyramiding allelic variants that block Xoo-induced sugar release might have an impact on pathogen fitness. In the current study, we accelerated the discovery of rice accessions with naturally mutated EBEs in the promoter sequence of two major susceptibility genes i.e. OsSWEET13 and OsSWEET14 by mining a vast diversity dataset. The identified SNP/InDels, which appears to block TALE-mediated activation of OsSWEET13 and OsSWEET14 (S4 Table), represent novel variations that appear to have emerged independently in rice subspecies. While Ejali and Khama1183 represent landraces from the aus subgroup, Super Basmati is the only improved variety that renders economic importance. Therefore, stacking OsSWEETs variants into SB to systematically control disease epidemics is a likely scenario in breeding programs from exporter countries. We also anticipate that protecting premium Basmati varieties against BB epidemic will effectively reduce yield loses and increase income to farmers.

Our results contribute to the hypothesis that OsSWEET14 represents a pivotal S-gene in the evolutionary history of Xoo. As far as we know, the promoter region contains three overlapping EBE targeted by unrelated TALEs [12]. While Asian and African Xoo appear to be genetically different [47], both groups evolved to target the same gene i.e. OsSWEET14. For instance, TalC and Tal5 from the African Xoo stains BAI3 and MAI1 targets EBEs located upstream and downstream of the overlapping target site of PthXo3 and AvrXa7, from Asian strains PXO61 and PXO86 [17]. Convergent evolution in geographically distant and unrelated pathogens suggests that the activation of OsSWEET14 was an essential event during Xoo adaptation to rice. As predicted by the arm race model, the selection pressure of the pathogen evolves mutation in rice host that prevents Xoo-mediated activation of OsSWEET14. Interestingly, these mutation events appeared in wild and domesticated rice backgrounds from different geographies, independently. Hutin et al. [42] identified a single 18-bp deletion in the African wild rice Oryza barthii that disrupts TalC until Tal5 EBEs. In this work, we report a novel substitution in the EBE of the Asian Oryza sativa subspecies. A single change in a cytosine residue (“C” to “G”), appears to be enough to prevent the activation of the gene, and emerged in the target region of Asian effectors PthXo3 and AvrXa7. This pattern of variation aligned with the overall idea that rice was domesticated in different geographies [48] but also that unrelated Xoo populations adapt to the same host through a key susceptibility target, independently.

Asian populations of Xoo appear to maintain members of the PthXo2 family to mediate the activation of OsSWEET13 during rice colonization [16, 15]. Similar to other studies [43, 14], our data suggest that mutations in the promoter region of OsSWEET13 emerged in japonica and indica, independently. So far, the pattern of variation in the promoter of OsSWEET13 suggests that Xoo might be driving the evolution of this gene. PthXo2 is not able to activate the japonica OsSWEET13 due to a single nucleotide deletion after TATA box region present in resistant varieties i.e. Zhonghua11, Nipponbare, Mudanjing 8, and Minghui 63 [43, 49, 14]. However, the same TALE has a cryptic binding site in the indica promoter of IR24 [14] pointing out to sub species-specific adaptations of PthXo2 members. It is likely that these mutations are maintained in the host populations by balancing selection, where effector diversity could be correlated with S-gene diversity.

So far, two variations at the EBE of OsSWEET13 have been reported to be susceptible in indica backgrounds i.e. IR24 and Zhenshan97 (ZS97) [50, 51, 14]. Both, OsSWEET13IR24 and OsSWEET13ZS97, can be activated by inoculations with PthXo2.1 and PthXo2-carrying Xoo strains [14, 50]. Interestingly, we identified a 2bp-deletion in OsSWEET13Khama1183 that aligned with the reported sequence of OsSWEET13ZS97 [14] (Fig 2). However, in our hands, OsSWEET13Ejali and OsSWEET13Khama1183 were not induced when infected with PthXo2 and PthXo2.1. The induction of OsSWEET13ZS97 may be explained by the presence of heterozygous alleles of OsSWEET13 in Zhenshan97 and homozygous in Khama1183. Alternatively, Zhenshan97 might have an unknown EBE on OsSWEET13, but further evidences are still needed to explain these differences in activation.

Overall, phenotypic assessment of resistance is often challenging due to background effect. The influence of a single nucleotide change might be masked by thousands of other variations in a genotype-specific manner. So at this stage we cannot discard the presence of other resistance genes that might contribute with the phenotype. The particular location of the SNP/InDel within the EBEs, and the lack of OsSWEET activation can be presumably correlated with disrupted EBEs in the promoter regions of OsSWEET13 and OsSWEET14. A further genetic analysis is underway and will validate the contribution of these variants to the overall phenotype.

Blocking Xoo access to nutrient sources in the rice environment is a promising strategy to gain resistance against BB. However, keeping in mind the genetic diversity of Xoo population across different rice growing regions, novel alleles with an expanded range of protection are necessary. Using this approach, we accelerated the discovery of valuable mutations in the rice germplasm. While the direct link between SNP/InDel and phenotype remains to be established for these accessions, our finding provide some hope these EBE variants will be suitable for introgression in elite varieties.

Conclusions

In modern agriculture, effective control of plant pathogen is one of the core objectives of crop improvement studies. Availability of better knowledge regarding pathogen and host molecular determinants has led to the development of more effective and comprehensive strategies for plant resistance mechanisms. Current study suggest that exploiting natural, loss of function allelic variants of major S genes and their introgression into elite genetic background would diversify the sources of resistance hence providing an additional layer of defense to sustain rice production in BB hotspot region.

Supporting information

S1 Table. List of 41 selected accession with SNP/InDels at the EBE of OsSWEET13 and OsSWEET14.

https://doi.org/10.1371/journal.pone.0203711.s001

(XLSX)

S2 Table. List of Xoo strains and their respective TAL effectors used in the study.

https://doi.org/10.1371/journal.pone.0203711.s002

(DOCX)

S3 Table. List of primer for EBE amplification and expression profiling of OsSWEET13 and OsSWEET14.

https://doi.org/10.1371/journal.pone.0203711.s003

(DOCX)

S4 Table. Summary of naturally existing altered EBEs of OsSWEET13 and OsSWEET14 in IR24, Ejali, Khama1183 and SB.

Activation and lack of activation of both genes in selected accessions by their corresponding TALe is represented with + and–symbol respectively.

https://doi.org/10.1371/journal.pone.0203711.s004

(DOCX)

S1 Fig. Alignment of PthXo1 RVDs with predicted EBE of OsSWEET11 and disease incidence of PXO99 on three selected accessions.

(A) Alignment of OsSWEET11 EBE in selected accessions with PthXo1 RVDs contained in PXO99 shows intact EBE without any natural variations. (B) Average lesion length represents susceptible phenotype of selected accessions i.e. Ejali, Khama1183, SB and IR24 inoculated PXO99. Accessions were clip inoculated and accessed for disease incidence 14 days post inoculation. Each bar represents average lesion length of three replicates. Vertical lines on each bar represents ± standard deviation (SD) among three replicates.

https://doi.org/10.1371/journal.pone.0203711.s005

(DOCX)

S2 Fig. Screening of selected 41 accessions, with SNPs/InDels at predicted EBE of OsSWEET13 and OsSWEET14, against PXO86, PXO61 and PXO339 carrying AvrXa7, PthXo3 and PthXo2.1 respectively.

Forty five days old plants were clip inoculated and disease incidence was measured at 14 dpi. Each bar represents average lesion length of three replicates and vertical lines on each bar represents ± standard deviation (SD) among three replicates of each Xoo strain. Asterisk indicates accession carrying pyramided SNPs/InDels in the predicted EBE of OsSWEET13 and OsSWEET14 with reduced disease incidence for three tested Xoo strains.

https://doi.org/10.1371/journal.pone.0203711.s006

(DOCX)

S3 Fig. Genotyping unveils presence and absence of xa5 gene in selected accessions.

SB, Ejali, Khama1183 and IR24 were genotyped using specific primers (Resistant forward/Susceptible forward + reverse). IRBB5 was used as positive control. Ejali and IRBB5 contain both alleles in homozygous state xa5/xa5, SB and IR24 have homozygous dominant (Xa5/Xa5) while Khama1183 is heterozygous (Xa5/xa5) both alleles.

https://doi.org/10.1371/journal.pone.0203711.s007

(DOCX)

Acknowledgments

Scientists at the International Rice Research Institute (IRRI) are partially funded by the Research Program on Rice Agri-food System (RICE). The program is supported by CGIAR. This work was partially funded by The Council of Agriculture (COA) in Taiwan, and USAID though the Agriculture Innovation Program (AIP) Pakistan fund. We thank Wolf Frommer and Frank White for useful comments.

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